亚-Ångstrom在扫描透射电子显微镜中通用探测器上的电场测量

IF 3.56 Q1 Medicine
Jordan A. Hachtel, Juan Carlos Idrobo, Miaofang Chi
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引用次数: 78

摘要

扫描透射电子显微镜(STEM)在原子尺度结构和化学方面表现优异。增强我们直接成像材料局部特征功能的能力已成为STEM未来发展中最重要的主题之一。最近,差分相对比成像(DPC)被用于从纳米尺度特征(如pn结、skyrmions,甚至单个原子)中绘制材料的内部电场和磁场。在这里,我们使用超低噪声SCMOS探测器作为衍射面相机来收集四维(4D)数据集。相机的高角度分辨率、高效的高信噪比采集和可修改性使其成为通用探测器,其中STEM成像配置,如DPC、亮场、环形亮场和环形暗场都可以从单个4D数据集重建。通过研究一种扭曲的钙钛矿DyScO3,它的投影晶格间距小至0.83?,我们演示了DPC空间分辨率几乎达到了100?keV电子束。此外,钙钛矿具有具有交替八面体倾斜的有序o配位,可以利用DPC对光原子的敏感性以单度精度进行定量测量。这些结果是在标准的Ronchigram相机上获得的,而不是专门的DPC探测器,为理解和设计涉及纳米和原子尺度的晶格和电荷耦合的功能材料和器件开辟了新的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Sub-Ångstrom electric field measurements on a universal detector in a scanning transmission electron microscope

Sub-Ångstrom electric field measurements on a universal detector in a scanning transmission electron microscope

Scanning transmission electron microscopy (STEM) excels in accessing atomic-scale structure and chemistry. Enhancing our ability to directly image the functionalities of local features in materials has become one of the most important topics in the future development of STEM. Recently, differential phase contrast (DPC) imaging has been utilized to map the internal electric and magnetic fields in materials from nanoscale features such as p–n junctions, skyrmions, and even from individual atoms. Here, we use an ultra-low noise SCMOS detector in as the diffraction plane camera to collect four-dimensional (4D) datasets. The high angular resolution, efficient high-SNR acquisition, and modifiability of the camera allow it to function as a universal detector, where STEM imaging configurations, such as DPC, bright field, annular bright field, and annular dark field can all be reconstructed from a single 4D dataset. By examining a distorted perovskite, DyScO3, which possesses projected lattice spacings as small as 0.83??, we demonstrate DPC spatial resolution almost reaching the information limit of a 100?keV electron beam. In addition, the perovskite has ordered O-coordinations with alternating octahedral tilts, which can be quantitatively measured with single degree accuracy by taking advantage of DPC’s sensitivity to light atoms. The results, acquired on a standard Ronchigram camera as opposed to a specialized DPC detector, open up new opportunities to understand and design functional materials and devices that involve lattice and charge coupling at nano- and atomic-scales.

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来源期刊
Advanced Structural and Chemical Imaging
Advanced Structural and Chemical Imaging Medicine-Radiology, Nuclear Medicine and Imaging
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